Analog-to-digital converting apparatus for processing a plurality of analog input signals at high rate and display device using the same

ABSTRACT

An analog-to-digital converting apparatus for rapidly processing a plurality of analog input signals at a high rate and a display device using the same. The apparatus includes a clock signal generator that generates a clock signal with a predetermined frequency; a control signal generator that generates a switching control signal using the clock signal; a multiplexer (MUX) that receives and selectively outputs signals of the plurality of analog input signals according to the switching control signal; and an analog-to-digital converter (ADC) that converts an analog signal selected and output by the MUX to a digital signal.

This is a divisional of application Ser. No. 10/892,443 filed Jul. 16,2004; the disclosure of which is incorporated herein by reference.

This application claims priority from Korean Patent Application No.2003-49134, filed on Jul. 18, 2003, in the Korean Intellectual PropertyOffice, the disclosure of which is incorporated herein in its entiretyby reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a signal processing apparatus, and moreparticularly, to an analog-to-digital converting apparatus for rapidlyprocessing a plurality of analog input signals and a display deviceusing the same.

2. Description of the Related Art

Typically, in order to convert a plurality of analog input signals todigital signals using an analog-to-digital converter (ADC) in a signalprocessing apparatus, an analog-to-digital converting apparatus as shownin FIG. 1 is used.

Referring to FIG. 1, a conventional analog-to-digital convertingapparatus includes a multiplexer (MUX) 110, an ADC 120, and amicroprocessor 130.

The MUX 110 receives multiple analog signals S₁, S₂, . . . , S_(N), andselects and outputs one of the input analog signals according to aswitching control signal SEL generated by the microprocessor 130.

The ADC 120 converts the analog signal output by the MUX 110 to adigital signal and outputs it to the microprocessor 130.

The microprocessor 130 generates the switching control signal SEL andprovides the SEL to a control terminal of the MUX 110 for controllingthe MUX 110. The microprocessor 130 also uses the digital signals outputby the ADC 120 in a predetermined control algorithm to produce somecontrol values.

The analog-to-digital converting apparatus may be applied to anapparatus such as an apparatus for an automatic color coherencecorrection. In this case, the predetermined control algorithmcorresponds to an automatic color coherence control algorithm, themultiple analog signals S₁, S₂, . . . , S_(n) S_(N), correspond tosignals that are detected by photo-sensors (not shown) arranged overdifferent positions on a screen, and the control values generated by themicroprocessor 130 correspond to RGB color coherence correction gainvalues.

However, in the conventional apparatus, the MUX works according to aswitching control signal SEL generated by the microprocessor 130, and soa data processing rate of the MUX is limited. Consequently, the samplingspeed for input analog signals is also limited to an extent. Moreparticularly, the increase in the number of a plurality of input analogsignals input to the MUX 130 causes harmful effects on the dataprocessing rate of the microprocessor 130. In addition, if the inputanalog signals are affected by any surrounding noise, such as an impulsenoise, data processing results may be erroneous.

SUMMARY OF THE INVENTION

The present invention provides an analog-to-digital converting apparatusfor processing a plurality of analog input signals at a high rate and adisplay device using the same.

According to an aspect of the present invention, there is provided ananalog-to-digital converting apparatus for rapidly processing aplurality of analog input signals, the apparatus comprising, a clocksignal generator that generates a clock signal with a predeterminedfrequency; a control signal generator that generates a switching controlsignal using the clock signal; a multiplexer (MUX) that receives andselectively outputs signals of the plurality of analog input signalsaccording to the switching control signal; and an analog-to-digitalconverter (ADC) that converts an analog signal selected and output bythe MUX to a digital signal. Further, the control signal generator maybe a counter circuit.

According to another aspect of the present invention, there is providedan analog-to-digital converting apparatus for rapidly processing aplurality of analog input signals, the apparatus comprising, a clocksignal generator that generates a clock signal with a predeterminedfrequency; a control signal generator that generates switching controlsignals and buffer control signals using the clock signal; a multiplexer(MUX) that receives and selectively outputs the plurality of analoginput signals according to the switching control signals; ananalog-to-digital converter (ADC) that converts an analog input signalselected and output by the MUX to a digital signal; a buffer memory thatsequentially stores the digital signals according to the buffer controlsignals in the unit of the number of the analog signals input to theMUX, the length of the digital signals corresponding to the number ofdigital filter taps, and sequentially outputs digital signals in theunit of the number of digital filter taps; a digital filter thatmultiplies each of the digital signals output by the buffer memory inthe unit of the number of digital filter taps by predetermined tapcoefficients to remove noise; and a register block that sequentiallystores the filtered digital signals output by the digital filter.Further, the control signal generator may be a counter circuit and thebuffer control signals may be generated in synchronization with a dataprocessing rate of the ADC.

According to still another aspect of the present invention, a displaydevice is provided comprising, a test signal generator that generates apredetermined test pattern signal; a Red/Green/Blue cathode-ray-tube(RGB CRT) driving unit that amplifies the predetermined test patternsignal by a gain value and outputs the amplified predetermined testpattern signal as an RGB signal; an RGB CRT that generates aphotoelectric signal that corresponds to the RGB signal output by theRGB CRT driving unit; a plurality of photo-sensors that are arrangedover predetermined positions on a display screen and detect thephotoelectric signals projecting into the RGB CRT; a plurality ofamplifiers that amplify photoelectric signals detected by the pluralityof photo-sensors; a control signal generator that generates a switchingcontrol signal and a buffer control signal using the clock signal; amultiplexer (MUX) that receives signals output by the plurality ofamplifiers and selectively outputs a signal according to the switchingcontrol signal; an analog-to digital converter (ADC) that converts ananalog signal output by the MUX to a digital signal; a buffer memorythat sequentially stores the digital signals in a unit of the number ofsignals input to the MUX, the length of the digital signalscorresponding to the number of digital filter taps, and sequentiallyoutputs the digital signals in the unit of the number of digital filtertaps; a digital filter that multiplies each of the digital signalsoutput by the buffer memory in the unit of the number of digital filtertaps by predetermined tap coefficients to remove noise; a register blockthat sequentially stores the filtered digital signals output by thedigital filter; and a microprocessor that reads a digital signal fromthe register block, uses the digital signal in a predetermined colorcoherency correction process, and generates a gain control signal forthe color coherence correction. Further, the control signal generatormay be a counter circuit and the buffer control signals may be generatedin synchronization with a data processing rate of the ADC.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other aspects and advantages of the present invention willbecome more apparent by describing in detail an exemplary embodimentthereof with reference to the attached drawings in which:

FIG. 1 is a schematic block diagram of a conventional analog-to-digitalconverting apparatus for converting a plurality of analog input signalsto digital signals;

FIG. 2 is a schematic block diagram of an analog-to-digital convertingapparatus for processing a plurality of analog input signals at a highrate, according to the present invention;

FIG. 3 is a schematic block diagram of a display device employing theanalog-to-digital converting apparatus for processing a plurality ofanalog input signals at a high rate, according to the present invention;and

FIG. 4 shows an embodiment of a data storage format in a buffer memory.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 2 is a schematic block diagram of an analog-to-digital convertingapparatus for processing a plurality of analog input signals at a highrate according to the present invention.

Referring to FIG. 2, the analog-to-digital converting apparatus includesa clock signal generator 210, a control signal generator 220, amultiplexer (MUX) 230, an analog-to-digital converter (ADC) 240, abuffer memory 250, a digital filter 260, a register block 270, and amicroprocessor 280.

The clock signal generator 210 generates a clock signal to be used togenerate a switching control signal applied to the MUX 230. Thefrequency of the clock signal is proportional to a frequency multiplierby which an input signal is multiplied. In this case, the frequency ofthe input signal corresponds to the frequency of a signal output by aphoto sensor, however, a conventional clock signal is generated bymultiplying the horizontal synchronous frequency (H-SYNC) of, forexample, a television.

The control signal generator 220 divides the frequency of the clocksignal and generates a switching control signal CS1 used by the MUX 230to select an input signal. The control signal generator 220 alsogenerates a buffer control signal CS2 to control a data storage rate andaccess timing of the buffer memory 250. The buffer control signal CS2should be generated so as to be in synchronization with the dataprocessing rate of the ADC 240. The control signal generator 220 can bedesigned, for example, as a counter circuit.

The MUX 230 receives multiple analog signals S₁, S₂, . . . , S_(N),selects one of the analog signals according to the switching controlsignal CS1 generated by the control signal generator 220, and outputsthe selected analog signal to the ADC 240.

The ADC 240 converts the analog signal received from the MUX 230 to adigital signal and outputs the digital signal to the buffer memory 250.

The buffer memory 250 sequentially stores the 1st through N-th digitalsignals converted by the ADC 240, the length of the digital signalscorresponding to the number of taps of the digital filter 260, accordingto the buffer control signal CS2, the format of which is shown in FIG.4. In FIG. 4, N is the number of input signals, and M is the number oftaps of the digital filter 260.

Specifically, the buffer memory 250 stores (digital) data of the inputsignals S₁-S_(N), by sequentially filling the first column with data inthe order of DATA 1-M, DATA 2-M, DATA 3-M, . . . , DATA N-M, and thenfilling the next column with data of DATA 1-(M-1), . . . , DATA N-(M-1).In this way, the buffer memory 250 can be filled with the data of all ofthe input signals S₁-S_(N). When the buffer memory 250 is filled withdata of all of the input signals S₁, S₂, . . . , S_(N), it begins tooutput data DATA 1-1, DATA 1-2, . . . , DATA1-M that correspond to theinput signal S₁, to the digital filter 260, and then sequentiallyoutputs remaining data that correspond to S₂, . . . , S_(N), in asimilar way.

The digital filter 260 (FIG. 2) performs digital filtering on the databy applying tap coefficients to data DATA1-1, DATA1-2, . . . , DATA1-Mand outputs the digital filtered data. In a similar way, remaining datathat correspond to input signals S₂, . . . , S_(N) aredigitally-filtered and output.

The register block 270, which is comprised of a plurality of registerarrays, sequentially stores the data output from the digital filter 260.

The microprocessor 280 reads data from the register block 270 andapplies a predetermined algorithm, such as the automatic color coherencecontrol algorithm, to the data to generate control values.

An embodiment of a display device employing the analog-to-digitalapparatus for rapidly processing a plurality of analog input signals,according to the present invention will now be described.

FIG. 3 shows a schematic diagram of a projection television, i.e., atype of display device, employing the analog-to-digital apparatus forrapidly processing a plurality of analog input signals, according to thepresent invention.

The projection television includes a clock signal generator 210, acontrol signal generator 220, a MUX 230, an ADC 240, a buffer memory250, a digital filter 260, a register block 270, a microprocessor 280,an input unit 290, a memory 300, a test signal generator 310, aswitching unit 320, a Red/Green/Blue cathode-ray-tube (RGB CRT) drivingunit 330, an RGB CRT 340, a plurality of photo-sensors 350 and aplurality of amplifiers 360.

Since the clock signal generator 210, the control signal generator 220,the MUX 230, the ADC 240, the buffer memory 250, the digital filter 260and the register block 270 are the same components as shown in FIG. 2,and have already been described in detail, an explanation thereof willbe omitted.

The input unit 290 has various kinds of keys to operate the projectiontelevision, and, in particular, key buttons to instruct the projectiontelevision to enter a color coherence correction mode.

The test signal generator 310 generates RGB test pattern signals tomeasure the intensity of each of the R, G, and B components of light atpositions on the screen during the color coherence correction mode, andthe test pattern signals for the R, G, B are applied to positions overwhich a plurality of photo-sensors 350 are arranged.

The switching unit 320 selects and outputs a processed television signalduring a television mode, and selects and outputs an RGB test patternsignal generated by the test signal generator 310 during the colorcoherence correction mode.

The RGB CRT driving unit 330 amplifies RGB signals by RGB gain valuesthat correspond to RGB gain control signals supplied by themicroprocessor 280 and outputs the result. During the color coherencecorrection mode, the RGB CRT driving unit 330 amplifies the RGB testpattern signals at positions by the RGB gain values for coordinates ofthe screen stored in the memory 300 as initial values.

The RGB CRT 340 outputs photoelectric signals that correspond to theamplified RGB test pattern signals at positions output by the RGB CRTdriving unit 330.

A plurality of photo-sensors 350 are arranged over a plurality ofpositions on the display screen. The photo-sensors detect photoelectricsignals projected on the display screen and convert them to electricalsignals.

A plurality of amplifiers 360 amplify each of the plurality ofelectrical signals detected by the photo-sensors 350, and output theamplified signals to the MUX 230.

The MUX 230 selects and outputs one of the multiple analog signalsoutput by the plurality of amplifiers 360 according to a switchingcontrol signal CS1 generated by the control signal generator 220, as inthe operation described above with reference to FIG. 2.

As described above with reference to FIG. 2, an analog signal outputfrom the MUX 230 is converted to a digital signal by the ADC 240, andthen the digital signal is input to the microprocessor 280 via thebuffer memory 250, digital filter 260 and register block 270.

The microprocessor 280 analyzes a key instruction generated by the inputunit 290, and controls overall components of the projection televisionaccording to the result obtained by analyzing the key instruction. Inparticular, microprocessor 280 controls the test signal generator 310 togenerate test pattern signals during the color coherence correctionmode, and controls the switching unit 320 to select test pattern signalsgenerated by the test signal generator 310 and output the selected testpattern signals to the RGB CRT driving unit 330.

In addition, the microprocessor 280 finds a position in which theintensity of each of RGB output by each of the photo-sensors is themaximum, from among initial intensity values at positions stored in thememory 300 at the initial stage of the color coherence correction mode,and controls the signal convergence of the RGB CRT driving unit 330. Themicroprocessor 280 also reads digital data of the input signals detectedby the photo-sensors 350 from the register block 270 during the colorcoherence correction mode and uses the digital data in a color coherencecorrection process program stored in the memory 300 to produce gaincontrol values for the color coherence correction.

During the color coherence correction process, the microprocessor 280compares digital data of the input signals by positions withcorresponding reference values, obtains a difference between a positionhaving the maximum RGB intensity output by one of the photo-sensors 350and a position having the maximum reference value, and performs aconvergence adjustment to compensate for the difference. That is, themicroprocessor adjusts the position having the maximum RGB intensityoutput by one of the photo-sensors 350 to conform with the positionhaving the maximum reference value, and then updates the memory 300 withthe convergence-adjusted values by positions.

As described above, the microprocessor 280 uses data read from theregister block 270 to control the convergence so as to bring positionsinto accurate color and focus.

The memory 300 stores a program and data to perform the color coherencecorrection process. The memory 300 also stores positions in which RGBintensity detected by the photo-sensors 350 is the maximum in each ofthe coordinates, as well as corresponding RGB intensity, as initialvalues. The initial values in the memory 300 are updated with laterconvergence-adjusted RGB values by positions, adjusted and determinedthrough the color coherence correction mode.

The switching control signal CS1 used by the MUX 230 to select an inputsignal, is generated by a counter circuit using a high frequency clocksignal, so that multiple input signals can be rapidly processed. Also,the digital filter 260 is used to remove exterior noise, thereby makingthe data more reliable.

Accordingly, as described above, with a frequency-divided clock signalgenerated by the clock signal generator 210, the MUX in theanalog-to-digital converting apparatus is controlled to performswitching, in a manner that allows the apparatus to rapidly process theinput analog signals. The digital signals can be further accuratelyprocessed by the digital filer 260 that removes exterior noise.

While this invention has been particularly shown and described withreference to exemplary embodiments thereof, it will be understood bythose skilled in the art that various changes in form and details may bemade therein without departing from the spirit and scope of theinvention as defined by the appended claims.

1. A display device comprising; a test signal generator that generates apredetermined test pattern signal; a Red/Green/Blue cathode-ray-tube(RGB CRT) driving unit that amplifies the predetermined test patternsignal by a gain value and outputs the amplified predetermined testpattern signal as an RGB signal; a RGB CRT that generates aphotoelectric signal that corresponds to the RGB signal output by theRGB CRT driving unit; a plurality of photo-sensors that are arrangedover predetermined positions on a display screen and detect thephotoelectric signals projecting into the RGB CRT; a plurality ofamplifiers that amplify photoelectric signals detected by the pluralityof photo-sensors; a control signal generator that generates a switchingcontrol signal and a buffer control signal using the clock signal; amultiplexer (MUX) that receives signals output by the plurality ofamplifiers and selectively outputs a signal according to the switchingcontrol signal; an analog-to digital converter (ADC) that convertsanalog signals output by the MUX to digital signals; a buffer memorythat sequentially stores the digital signals corresponding to the numberof signals input to the MUX, the length of the digital signalscorresponding to a number of digital filter taps, and sequentiallyoutputs the digital signals corresponding to the number of digitalfilter taps; a digital filter that multiplies each of the digitalsignals output by the buffer memory corresponding to the number ofdigital filter taps by predetermined tap coefficients to remove noise; aregister block that sequentially stores filtered digital signals outputby the digital filter; and a microprocessor that reads a digital signalfrom the register block, uses the digital signal in a predeterminedcolor coherency correction process, and generates a gain control signalfor the color coherence correction.
 2. The display device of claim 1,wherein the control signal generator comprises a counter circuit.
 3. Thedisplay device of claim 1, wherein the buffer control signals aregenerated in synchronization with a data processing rate of the ADC.